PSA-NCAM Regulatory Gene Expression Changes in the Alzheimer's Disease Entorhinal Cortex Revealed with Multiplexed in situ Hybridization.

BACKGROUND: Alzheimer's disease (AD) is the most common form of dementia and is characterized by a substantial reduction of neuroplasticity. Our previous work demonstrated that neurons involved in memory function may lose plasticity because of decreased protein levels of polysialylated neural cell adhesion molecule (PSA-NCAM) in the entorhinal cortex (EC) of the human AD brain, but the cause of this decrease is unclear. OBJECTIVE: To investigate genes involved in PSA-NCAM regulation which may underlie its decrease in the AD EC. METHODS: We subjected neurologically normal and AD human EC sections to multiplexed fluorescent in situ hybridization and immunohistochemistry to investigate genes involved in PSA-NCAM regulation. Gene expression changes were sought to be validated in both human tissue and a mouse model of AD. RESULTS: In the AD EC, a cell population expressing a high level of CALB2 mRNA and a cell population expressing a high level of PST mRNA were both decreased. CALB2 mRNA and protein were not decreased globally, indicating that the decrease in CALB2 was specific to a sub-population of cells. A significant decrease in PST mRNA expression was observed with single-plex in situ hybridization in middle temporal gyrus tissue microarray cores from AD patients, which negatively correlated with tau pathology, hinting at global loss in PST expression across the AD brain. No significant differences in PSA-NCAM or PST protein expression were observed in the MAPT P301S mouse brain at 9 months of age. CONCLUSION: We conclude that PSA-NCAM dysregulation may cause subsequent loss of structural plasticity in AD, and this may result from a loss of PST mRNA expression. Due PSTs involvement in structural plasticity, intervention for AD may be possible by targeting this disrupted plasticity pathway.

Functional Characterization of C-terminal Ryanodine Receptor 1 Variants Associated with Central Core Disease or Malignant Hyperthermia.

BACKGROUND: Central core disease and malignant hyperthermia are human disorders of skeletal muscle resulting from aberrant Ca2+ handling. Most malignant hyperthermia and central core disease cases are associated with amino acid changes in the type 1 ryanodine receptor (RyR1), the skeletal muscle Ca2+-release channel. Malignant hyperthermia exhibits a gain-of-function phenotype, and central core disease results from loss of channel function. For a variant to be classified as pathogenic, functional studies must demonstrate a correlation with the pathophysiology of malignant hyperthermia or central core disease. OBJECTIVE: We assessed the pathogenicity of four C-terminal variants of the ryanodine receptor using functional analysis. The variants were identified in families affected by either malignant hyperthermia or central core disease. METHODS: Four variants were introduced separately into human cDNA encoding the skeletal muscle ryanodine receptor. Following transient expression in HEK-293T cells, functional studies were carried out using calcium release assays in response to an agonist. Two previously characterized variants and wild-type skeletal muscle ryanodine receptor were used as controls. RESULTS: The p.Met4640Ile variant associated with central core disease showed no difference in calcium release compared to wild-type. The p.Val4849Ile variant associated with malignant hyperthermia was more sensitive to agonist than wild-type but did not reach statistical significance and two variants (p.Phe4857Ser and p.Asp4918Asn) associated with central core disease were completely inactive. CONCLUSIONS: The p.Val4849Ile variant should be considered a risk factor for malignant hyperthermia, while the p.Phe4857Ser and p.Asp4918Asn variants should be classified as pathogenic for central core disease.

Functional characterization of 2 known ryanodine receptor mutations causing malignant hyperthermia.

BACKGROUND: Malignant hyperthermia (MH) is a potentially lethal pharmacogenetic disorder. More than 300 variants in the ryanodine receptor 1 (RYR1) have been associated with MH; however, only 31 have been identified as causative. To confirm a mutation in RYR1 as being causative for MH, segregation of the potential mutation in at least 2 unrelated families with MH susceptibility must be demonstrated and functional assays must show abnormal calcium release compared with wild-type RYR1. METHODS: We used "Hot-spot" DNA screening to identify mutations in RYR1 in 3 New Zealand families. B-lymphoblastoid cells were used to compare the amount of calcium released on stimulation with 4-chloro-m-cresol between wild-type RYR1 cells and cells carrying the new variants in RYR1. RESULTS: We identified a known RYR1 mutation (R2355W) in 2 families and another more recently identified (V2354M) mutation in another family. Both mutations segregated with MH susceptibility in the respective families. Cell lines carrying a mutation in RYR1 showed increased sensitivity to 4-chloro-m-cresol. CONCLUSIONS: We propose that R2355W is confirmed as being an MH-causative mutation and suggest that V2354M is a RYR1 mutation likely to cause MH.